54
1 Wintertime organic and inorganic aerosols in Lanzhou, China: 1 Sources, processes and comparison with the results during 2 summer 3 4 J. Xu 1 , J. Shi 2 , Q. Zhang 3 , X. Ge 4 , F. Canonaco 5 , A. S. H. Prévôt 5, 6 , M. Vonwiller 7 , S. 5 Szidat 7 , J. Ge 2 , J. Ma 8 , Y. An 1 , S. Kang 1 , D. Qin 1 6 1 State Key Laboratory of Cryospheric Sciences, Cold and Arid Regions Environmental 7 and Engineering Research Institute, CAS, Lanzhou 730000, China 8 2 Key Laboratory for Semi-Arid Climate Change of the Ministry of Education, College of 9 Atmospheric Sciences, Lanzhou University, Lanzhou 730000, China 10 3 Department of Environmental Toxicology, University of California, Davis, CA 95616, 11 USA 12 4 Jiangsu Key Laboratory of Atmospheric Environment Monitoring and Pollution Control 13 (AEMPC), School of Environmental Science and Engineering, Nanjing University of 14 Information Science & Technology, Nanjing 210044, China 15 5 Laboratory of Atmospheric Chemistry, Paul Scherrer Institute (PSI), Villigen 5232, 16 Switzerland 17 6 State Key Laboratory of Loess and Quaternary Geology and Key Laboratory of Aerosol 18 Chemistry and Physics, Institute of Earth Environment, Chinese Academy of Sciences, 19 710075 Xi’an, China 20 7 Department of Chemistry and Biochemistry & Oeschger Centre for Climate Change 21 Research, University of Bern, Berne, 3012, Switzerland 22 8 College of Earth Environmental Science, Lanzhou University, Lanzhou 730000, China 23 24 Correspondence to: J. Xu ([email protected]) 25

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Page 1: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

1

Wintertime organic and inorganic aerosols in Lanzhou, China: 1

Sources, processes and comparison with the results during 2

summer 3

4

J. Xu1, J. Shi2, Q. Zhang3, X. Ge4, F. Canonaco5, A. S. H. Prévôt5, 6, M. Vonwiller7, S. 5

Szidat7, J. Ge2, J. Ma8, Y. An1, S. Kang1, D. Qin1 6

1State Key Laboratory of Cryospheric Sciences, Cold and Arid Regions Environmental 7

and Engineering Research Institute, CAS, Lanzhou 730000, China 8

2Key Laboratory for Semi-Arid Climate Change of the Ministry of Education, College of 9

Atmospheric Sciences, Lanzhou University, Lanzhou 730000, China 10

3Department of Environmental Toxicology, University of California, Davis, CA 95616, 11

USA 12

4Jiangsu Key Laboratory of Atmospheric Environment Monitoring and Pollution Control 13

(AEMPC), School of Environmental Science and Engineering, Nanjing University of 14

Information Science & Technology, Nanjing 210044, China 15

5Laboratory of Atmospheric Chemistry, Paul Scherrer Institute (PSI), Villigen 5232, 16

Switzerland 17

6State Key Laboratory of Loess and Quaternary Geology and Key Laboratory of Aerosol 18

Chemistry and Physics, Institute of Earth Environment, Chinese Academy of Sciences, 19

710075 Xi’an, China 20

7Department of Chemistry and Biochemistry & Oeschger Centre for Climate Change 21

Research, University of Bern, Berne, 3012, Switzerland 22

8College of Earth Environmental Science, Lanzhou University, Lanzhou 730000, China 23

24

Correspondence to: J. Xu ([email protected]) 25

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2

26

Abstract 27

Lanzhou, which is located in a steep Alpine valley in western China, is one of the most 28

polluted cities in China during the wintertime. In this study, an Aerodyne high resolution 29

time-of-flight aerosol mass spectrometer (HR-ToF-AMS), a seven-wavelength 30

aethalometer, and a scanning mobility particle sizer (SMPS) were deployed during 31

January 10 to February 4, 2014 to study the mass concentrations, chemical processes, and 32

sources of sub-micrometer particulate matter (PM1). The average PM1 concentration 33

during this study was 57.3 µg m−3 (ranging from 2.1 to 229.7 µg m−3 for hourly averages) 34

with organic aerosol (OA) accounting for 51.2%, followed by nitrate (16.5%), sulphate 35

(12.5%), ammonium (10.3%), black carbon (BC, 6.4%), and chloride (3.0%). The mass 36

concentration of PM1 during winter was more than twice the average value observed at 37

the same site in summer 2012 (24.5 µg m−3), but the mass fraction of OA was similar in 38

the two seasons. Nitrate contributed a significantly higher fraction to the PM1 mass in 39

winter compared to summer (16.5% vs. 10%), largely due to more favoured partitioning 40

to the particle phase at low air temperature. The mass fractions of both OA and nitrate 41

increased by ~5% (47% to 52% for OA and 13% to 18% for nitrate) with the increase of 42

the total PM1 mass loading, while the average sulphate fraction decreased by 6% (17% to 43

11%), indicating the importance of OA and nitrate for the heavy air pollution events in 44

Lanzhou. The size distributions of OA, nitrate, sulphate, ammonium, and chloride all 45

peaked at ~500 nm with OA being slightly broader, suggesting that aerosol particles were 46

internally mixed during winter, likely due to frequently calm and stagnant air conditions 47

during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 48

49

The average mass spectrum of OA showed a medium oxidation degree (average O/C 50

ratio of 0.28), which was lower than that during summer 2012 (O/C = 0.33). This is 51

consistent with weaker photochemical processing during winter. Positive matrix 52

factorization (PMF) with the multi-linear engine (ME-2) solver identified six OA sources, 53

i.e., a hydrocarbon-like OA (HOA), a biomass burning OA (BBOA), a cooking-emitted 54

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3

OA (COA), a coal combustion OA (CCOA), and two oxygenated OA (OOA) factors. 55

One of the OOAs was less-oxidized (LO-OOA) and the other one of more-oxidized (MO-56

OOA). LO-OOA was the most abundant OA component (22.3% of OA mass), followed 57

by CCOA (22.0%), COA (20.2%), MO-OOA (14.9%), BBOA (10.8%), and HOA (9.8%). 58

The mass fraction of primary OA (= HOA + BBOA + COA + CCOA) increased during 59

high PM pollution periods, indicating that local primary emissions were a main reason for 60

the formation of air pollution events in Lanzhou during winter. Radiocarbon (14C) 61

measurement was conducted on four PM2.5 filter samples from this study, which allowed 62

for a quantitative source apportionment of organic carbon (OC). The non-fossil sources 63

on average accounted for 55 ± 3% of OC which could be mainly from biomass burning 64

and cooking activities, suggesting the importance of non-fossil sources for the PM 65

pollution in Lanzhou. Combining with the PMF results, we also found that a large 66

fraction (66%) of the secondary OC was from non-fossil OC. 67

68

1 Introduction 69

Frequent haze pollution events in urban areas in China have been a widespread concern 70

in recent years due to its high adverse health effects, visibility degradation and climate 71

effects (Chan and Yao, 2008). The Chinese Central Government had put in extensive 72

efforts to find urgent and suitable control strategies to reduce further deterioration of air 73

quality. Strategies such as promoting energy conservation and emission reduction 74

measures and new air quality standards (PM2.5 currently vs. PM10 in the past) have been 75

implemented in the last three years (http://www.gov.cn/zwgk/2013-76

09/12/content_2486773.htm). Many local governments have also launched measures such 77

as shutting down some highly polluting factories and restricting the use of private 78

vehicles to reduce air pollution in their cities. However, air pollution in China is still far 79

from being controlled due to its complex sources and limited knowledge on the multiple 80

pathways leading to secondary aerosol formation and dynamic variation of aerosol mass 81

loading. 82

83

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Lanzhou, the capital of Gansu province, is located at the northwest of China and has 84

experienced air pollution issues since the 1960s due to emissions from the petrochemical 85

industry and its valley terrain which tended to form stagnant meteorological conditions 86

(Tang et al., 1985; Zhang et al., 2000). Air pollution is still serious and has become more 87

variable in recent years (since 2000) because of fast urbanization and increased energy 88

consumption. The severity of air pollution often reaches maximum intensity during 89

winter due to coal combustion for domestic heating and cooking, similar to the situations 90

in most cities of northern China (Wang et al., 2014). Despite the serious air pollution 91

during winter in Lanzhou, aerosol chemistry, sources, and formation and transformation 92

processes were poorly documented in the literature, which limit the development and 93

implementation of efficient control strategies. 94

95

The chemical and physical properties of atmospheric aerosol particles during winter, 96

especially during haze episode, have been recently investigated in metropolitan cities in 97

Eastern China (Sun et al., 2006; Zhao et al., 2013; Huang et al., 2014; Sun et al., 2014). 98

For example, the mean aerosol optical depth at 500 nm were up to ~0.7 during the month-99

long heavy haze pollution episode during January 2013 in Beijing (Bi et al., 2014); The 100

airborne microbes were found in particulate matter (PM) during hazy period which may 101

potentially include respiratory microbial allergens and pathogens (Cao et al., 2014). 102

Collection and analysis of filter samples have enabled quantification of the chemical 103

composition of PM using a suite of off-line instruments (such as ion chromatography, 104

organic and element carbon analyzer, inductively coupled plasma-mass spectrometry and 105

so on) in the laboratory (He et al., 2001; Zheng et al., 2005; Sun et al., 2006; Sun et al., 106

2011a; Zhang et al., 2013; Zhao et al., 2013), but often incapable of capturing details of 107

the atmospheric evolution processes during the typical lifecycle of aerosol. 108

109

Previous studies on source apportionment of aerosol particle identified dust, traffic, 110

industry, cooking-related activities, and secondary formation as important contributors, 111

although the contributions of individual sources may change drastically with location, 112

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season, and different apportionment algorithms (Zheng et al., 2005; Yu et al., 2013; 113

Huang et al., 2014). For example, Zheng et al. (2005) used chemical mass balance 114

(CMB) receptor model to quantitatively apportion the sources that contribute to fine PM 115

concentration in Beijing and found coal combustion contributed 16% of fine PM mass in 116

January. By contrast, principal component analysis of the same dataset estimated almost 117

twice amount of aerosols from coal combustion (Song et al., 2006). Source 118

apportionment techniques, such as the positive matrix factorization (PMF) allow us to use 119

thousands of fragment ions for source identification and use the real measurement 120

uncertainties to constrain the fitting, and would thus appear more suitable to identify and 121

apportion PM to their sources (Ulbrich et al., 2009). Compared with the number of 122

aerosol source apportionment studies using PMF in Eastern China (e.g., Sun et al., 2013b; 123

Zhang et al., 2013), there were fewer studies in inland cities of China (Elser et al., 2016), 124

the results of which can be used for inter-comparison and understanding the difference of 125

aerosol pollution in different parts of China. In addition, it has been known that a large 126

mass fraction of ambient PM during haze episodes is from fine particles, of which 127

secondary species (some carbonaceous components, sulphate, nitrate, and ammonium) 128

are major components (Zhao et al., 2013). However, the formation and evolution 129

mechanisms of those secondary species were poorly understood, and previous models 130

tended to underestimate the secondary species budget in polluted regions (e.g., Volkamer 131

et al., 2006; Carlton et al., 2010; Hodzic et al., 2016). 132

133

Online instruments based on mass spectrometric techniques, such as Aerodyne aerosol 134

mass spectrometer (AMS) (Jayne et al., 2000), have advantages on probing the fast 135

aerosol chemical processes because of the instrument can output data with a large amount 136

of chemical information and its fine time resolution (in minutes) and mass sensitivity (in 137

ng m-3) (Canagaratna et al., 2007). Aerodyne high resolution time-of-flight mass 138

spectrometer (HR-ToF-AMS) have been widely employed for the chemical 139

characterization of submicron aerosol (PM1) (DeCarlo et al., 2006), which provides on-140

line quantitative mass spectra of the non-refractory (inorganic and organic) aerosol 141

components with high time resolution. Frequently, the organic aerosol (OA) can be 142

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further analyzed using the PMF algorithm (Ulbrich et al., 2009; Zhang et al., 2011a), 143

which can represent the organic mass spectral matrix as a set of source/process-related 144

factor mass spectra and time series. In addition, carbon isotope technique has been 145

recently applied to quantify the fossil/non-fossil origins of carbonaceous aerosols, and in 146

combination with AMS-PMF analyses, the assessment of the origin of secondary organic 147

aerosol (SOA) became possible (Minguillon et al., 2011; Huang et al., 2014; Zotter et al., 148

2014; Beekmann et al., 2015). 149

150

In a previous study, we used an HR-ToF-AMS to investigate the chemical characteristics 151

of PM1 in the urban area of Lanzhou during summer 2012 (Xu et al., 2014). During that 152

study, organics in PM1 was found to mainly originate from traffic, cooking activities, and 153

chemical reactions which produced semi-volatile and less-volatility oxygenated OA. 154

Compared to summer situation, energy consumption for heating is huge during winter 155

and the dry and stable meteorological condition in the valley leads to longer aerosol 156

lifetime during winter. Thus aerosols are influenced largely by very different 157

meteorological conditions and chemical processes between the two seasons. More 158

intensive measurements of PM chemical characteristics are needed to better understand 159

aerosol sources, to quantify their lifetime in the atmosphere and to constrain the 160

uncertainties of their climatic influences. During winter of 2013/2014, we conducted such 161

a study at an urban site of Lanzhou. In this paper, we focus on the chemical speciation of 162

PM1 and source apportionment of OA. 163

164

2 Measurement and methods 165

2.1 Sampling site 166

Aerosol particle measurements were conducted from January 10 to February 4, 2014, at 167

the top floor of a twenty-two story building (~70 m a.g.l) (36.05°N; 103.85°W, 1569 m 168

a.s.l) in the campus of Lanzhou University (Fig. S1a). The campus is located in the 169

Chenguan district of Lanzhou which is a cultural and educational area. The twenty-two 170

story building sits at the western edge of the campus and faces a south-northern arterial 171

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road (Fig. S1a). At the campus side of this building, there is a three story dining hall of 172

Lanzhou University, and over the arterial road side, there are many restaurants and 173

residents. The room temperature was kept at ~20 °C by a central heating radiator. The 174

weather in Lanzhou during the campaign was cold (avg. T = 0.5 °C) and dry (avg. RH = 175

28%), and was influenced by the Asian winter monsoon. Because Lanzhou is surrounded 176

by mountains, atmospheric condition is normally stable with low wind speed (on average 177

0.82 m s−1 during this study). The sampling site represents a typical urban area dominated 178

by residential and commercial area. 179

180

2.2 Instruments 181

The physiochemical properties of aerosol particles were monitored in real-time by a suite 182

of instruments (Fig. S1b). The sampling inlet, constructed using 0.5 inch copper tube, 183

stemmed out of the rooftop by about 1.5 m. A PM2.5 cyclone (model URG-2000-30EH, 184

URG Corp., Chapel Hill, NC, USA) was used for removing coarse particles. The length 185

of the sampling line was about 5 m. A diffusion dryer was placed upstream of this line to 186

eliminate potential RH effect on particles. The inlet was shared by an Aerodyne HR-ToF-187

AMS (Aerodyne, Inc., Billerica, MA, USA) for the size-resolved chemical speciation of 188

non-refractory sub-micrometer PM (NR-PM1), a single particle intra-cavity laser induced 189

incandescence photometer (SP2, DMT, Inc., Boulder, CO, USA) for refractory black 190

carbon (rBC) measurement, a customer-made scanning mobility particle sizer (SMPS) 191

(Wiedensohler et al., 2012) for measuring particle size distribution between 10-800 nm, 192

and a 7-λ aethalometer (model AE31, Magee Scientific, Berkeley, CA, USA) to derive 193

the mass concentration of light absorbing black carbon (BC) particles. The total air flow 194

rate from the inlet was ~ 16 L min−1, with a vacuum pump drawing the air at a flow rate 195

of 10 L min−1 and the other 6 L min-1 sampled by the instruments. The retention time of 196

particles in the sampling line was less than 2.5 s. A parallel inlet with a 1:10 dilution 197

stage was setup for real-time PM2.5 measurement using a tapered element oscillating 198

microbalance (TEOM series 1400a, R&P, East Greenbush, NY, USA). The roof of the 199

building also hosted instruments for monitoring meteorological parameters such as 200

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visibility, air temperature, wind direction, wind speed, and RH. The visibility was 201

measured with a LED-based (880 nm) forward (42°) scattering visibility sensor (model 202

M6000, Belfort Ins., Maryland, USA). 203

204

2.2.1 HR-ToF-AMS operation 205

A detailed description of the principle and design of HR-ToF-AMS can be found 206

elsewhere (Jayne et al., 2000; DeCarlo et al., 2006). Briefly, HR-ToF-AMS consists of 207

three major sections: the inlet system, the particle sizing vacuum chamber, and the 208

particle composition detection section. The combination of a 100 µm orifice and an 209

aerodynamic lens in the inlet system are used to focus the airborne particles into a 210

concentrated and narrow beam, and then accelerated into the vacuum chamber (~105 211

Torr) modulated by a chopper for measuring aerodynamic size of the particle; Before 212

being detected, the particles are flash vaporized under 600 °C and ionized by a 70 eV 213

electron impact, and finally detected by the high resolution time-of-flight mass 214

spectrometer. The chopper works at three positions alternately, i.e., an open position 215

which transmits the particle beam continuously, a close position which blocks the particle 216

beam completely, and a chopping position which modulates the beam transmission (2% 217

duty cycle). The open and close positions yield the bulk and background signals for the 218

airborne particle, respectively, while the chopping position modulates the particle beam 219

by spinning chopper wheel (~150 Hz) to yield size-resolved spectral signals. The mass 220

spectrometer in the detection section works in two modes based on the shape of the ion 221

path, i.e., V-mode and W-mode, with high sensitivity and high chemical resolution 222

(~6000 m/∆m), respectively. The highly sensitive V-mode signals are usually used for 223

reporting mass concentration, while the high chemical resolution W-mode signals are 224

used for the analyses of mass spectrum. The time resolution for both V and W modes was 225

5 min. Under V-mode, the instrument switched between the mass spectrum mode and the 226

PToF mode every 15 s, spending 6 and 9 s on each, and cycled 20 times in one run; No 227

PToF data were recorded in W-mode due to low signal-to-noise (S/N) ratios. 228

229

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The instrument was calibrated for ionization efficiency (IE), inlet flow rate, and particle 230

sizes using the standard procedure described by (Jayne et al., 2000). For example, the size 231

calibration was performed following the general protocol used in the AMS community. 232

We used standard polystyrene latex (PSL) spheres (Duke Scientific Corp., Palo Alto, CA) 233

(100-700nm) and mono-dispersed ammonium nitrate particles (100-300nm), respectively. 234

These three calibrations were performed at the beginning, in the middle and end of the 235

field study. Particle-free ambient air was sampled at the end of the study to determine the 236

detection limits (DLs) of individual species and also for adjusting the fragmentation 237

table. Note that since no in-situ measurement of gas phase CO2, the subtraction of a 238

constant CO2 signal (400 ppm based on filtered-air measurement in this study) may 239

introduce uncertainties in the quantification of the organic-CO2+ signal. However, this 240

artifact was expected to be small (less than 5% error in organic-CO2+ quantification) due 241

to the high OA concentration (Xu et al., 2014). Default relative ionization efficiency 242

(RIE) values were assumed for organics (1.4), nitrate (1.1), sulphate (1.2), and chloride 243

(1.3), while an RIE value of 3.9 was determined for ammonium following the analysis of 244

pure NH4NO3. The close concentrations between measured ammonium and predicted 245

ammonium based on the stoichiometric charge balance between nitrate, sulphate, and 246

chloride (slope = 0.94, Fig. S4) suggest that these RIE values are suitable for this 247

campaign. 248

249

2.2.2 Operations of other instruments 250

The SMPS consisting of a condensation particle counter (CPC) (TSI, model 3772) and a 251

differential mobility analyser (DMA) was deployed at 5 min interval. Sample and sheath 252

flow rates of the DMA were set to 1 L min−1 and 5 L min−1, respectively. The SMPS was 253

calibrated using a polystyrene latex (PSL) standard prior to field measurements. 254

255

The SP2 uses an intra-cavity Nd:YAG laser at 1064 nm to determine the light scattering 256

and laser-induced incandescence of individual rBC (namely material associated with a 257

strongly absorbing component at 1064 nm). The SP2 incandescence signal was used to 258

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obtain single particle rBC mass after calibration with Aquadag standard BC particles. The 259

measured rBC mass is converted to a mass equivalent diameter, which is termed as the 260

BC core diameter (Dc) - the diameter of a sphere containing the same mass of rBC as 261

measured in the particle. Any measured particle with a detectable incandescence signal is 262

referred to as an rBC particle, whereas a particle which only exhibits a scattering signal is 263

termed as a non-BC particle. The total rBC mass loading is reported as the sum of all 264

detected single particle rBC masses. 265

266

The aethalometer measures the optical attenuation (absorbance) of light from LED lamps 267

emitting at seven wavelengths (370, 470, 520, 590, 660, 880, and 950 nm) with a typical 268

half-width of 20 nm. The difference in light transmission through the particle-laden 269

sample spot and a particle free reference spot of the filter is attributed to the absorption 270

caused by aerosol. The attenuation of light is converted to the BC mass concentration 271

using wavelength-dependent calibration factors as recommended by the manufacturer. 272

BC was measured using data at 880 nm using a specific attenuation cross section of 16.6 273

m2 g−1 during the campaign. The flow rate was maintained at 4.8 L min−1 calibrated using 274

a flow meter. Detection limit of the aethalometer BC was determined to be 0.16–0.28 µg 275

m−3 with a flow rate of 4.8 LPM and 5 min time interval, calculated as three times the 276

standard deviation (3σ) of the dynamic blanks. The TEOM was operated at a temperature 277

of 40 °C other than normal operation condition (50 °C) to dry the aerosol in order to 278

minimize mass loss due to volatilization of semi-volatile aerosol compounds. The time 279

resolution of PM2.5 mass concentration was 5 min. 280

281

2.3 Data processing 282

2.3.1 General AMS data processing 283

The HR-ToF-AMS data were processed using the standard software of SQUIRREL 284

(v1.56) and PIKA (v1.15c) (http://cires.colorado.edu/jimenez-285

group/ToFAMSResources/ToFSoftware/index.html) to determine the mass 286

concentrations and the size distributions of the NR-PM1 species and the ion-speciated 287

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mass spectra of organics, written in IGOR (Wavemetrics, Inc., Lake Oswego, OR, USA). 288

An empirical particle collection efficiency (CE) of 0.5 was used, which has been widely 289

used in field studies employing AMS with a dryer installed in front of the equipment's 290

particle inlet. This CE value was further validated by the consistency and reasonable 291

slope between HR-ToF-AMS measured mass concentrations and SMPS-determined 292

particle volumes (section 3.1.2, R2 = 0.9, slope = 1.48). The elemental ratios of OA (O:C, 293

H:C, and OM:OC) for this study was determined using the "Aiken ambient" method 294

(Aiken et al., 2008) other than the "improved-ambient" method (Canagaratna et al., 2015) 295

which increased O:C on average by 27%, H:C on average by 10%, and OM:OC on 296

average by 7% (Fig. S2). These "Aiken ambient" results of elemental ratios are more 297

suitable here to allow for comparison with those during summer 2012. 298

299

2.3.2 Positive Matrix Factorization (PMF) analyses 300

The source decomposition of organics was analysed by PMF with the multilinear engine 301

(ME-2) algorithm which serves to reduce rotational ambiguity within the PMF2 302

algorithm. The ME-2 algorithm allows the user to add a priori information into the model 303

(e.g., source profiles) to constrain the matrix rotation and separate the mixed solution or 304

the weak solution. The PMF analysis of organic matrix using ME-2 algorithm is 305

implemented within the toolkit SoFi (Source Finder) and perform by the so-called a-value 306

approach (Canonaco et al., 2013). First, organic matrix was analysed using the PMF2.exe 307

algorithm in robust mode (Paatero and Tapper, 1994) and explored using the PMF 308

Evaluation Toolkit (PET) (Ulbrich et al., 2009). The PMF solution was evaluated 309

following the procedures outlined in Table 1 of Zhang et al. (2011a) including 310

modification of the error matrix and downweight of low S/N ions. Moreover, based on 311

the AMS fragmentation table, some organic ions were not directly measured but scaled to 312

the organic signal at m/z 44, which were downweighted by increasing their errors by a 313

factor of 3. Some highly polluted periods were deleted during PMF analysis such as 314

January 22-23, 2014. The results of four, five, and six factor solutions with fPeak at 0 are 315

shown in supplementary material (Fig. S5-S7). It is easy to find that a coal combustion-316

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emitted OA (CCOA) factor, a cooking-emitted OA (COA) factor, a less-oxidized and 317

more-oxidized OA (LO-OOA and MO-OOA) factors could be clearly separated in the 318

four-factor solution; for the CCOA factor, there were significant contributions from m/z 319

55, 57, 60, 73, 91, and 115 in the mass spectrum, suggesting a mixing of multiple 320

sources. In the five-factor solution, a hydrocarbon-like OA (HOA) factor was separated; 321

however, m/z 60 and 73 which are related to biomass burning OA (BBOA) could not be 322

separated. We then performed OA source apportionment using the ME-2 algorithm by 323

constraining the profiles of HOA and BBOA with the fixed a-value of 0.1 for HOA and 324

0.4 for BBOA. The a-value test was performed following the technical guidelines 325

presented in Crippa et al. (2014). The reference profile of HOA was adopted from the 326

HOA of the summer study and the reference profile of BBOA was adopted from the nine-327

factor PMF solution of this study. 328

329

The size distributions of individual OA factors were determined via a multivariate linear 330

regression technique (Ge et al., 2012). This algorithm assumes that each OA mass 331

spectrum is the linear superposition of the mass spectra of individual OA factors, whose 332

mass profiles are constant across the whole size range. Further details about the algorithm 333

can be found in Xu et al. (2014). 334

335

2.3.3 Radiocarbon (14C) data analysis 336

In order to identify the origins of SOA, we conducted 14C analysis on four filter samples. 337

These filter samples were collected at the CAEERI site which is about 500 m away from 338

the LZU site (Fig. S1a). Filter samples were collected using a low volume PM2.5 sampler 339

(16.7 L min−1) during January 2014 with a 24 h sampling time in every week for each 340

filter (January 3rd, 8th, 15th, and 23rd, respectively) on pre-baked quartz filters. One 341

field blank filter was collected and analysed to correct the filter sample measurements. 342

Here, we use the results of these four filter samples to roughly represent the average 343

situation of the field sampling because of the relative stable meteorological conditions 344

(section 3.1.1) and similar aerosol sources during the field study (section 3.1.3). Due to 345

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the limitation of the small amount of filter samples, the results based on this carbon 346

isotopic data are preliminary and comprehensive validation is an ongoing work. Organic 347

carbon (OC) was separated from the filters by combustion at 375 °C during 200s in pure 348

oxygen in a thermo-optical OC/EC analyser (Model 4L, Sunset Laboratory Inc, USA) 349

(Zhang et al., 2012). The carbon isotopic analysis was conducted by online coupling of 350

the OC/EC analyser with the accelerator mass spectrometry system MICADAS at the 351

University of Bern, Switzerland (Zotter et al., 2014; Agrios et al., 2015). Fossil 14C 352

measurement results were transferred into the non-fossil fraction (fNF) of OC using a 353

conversion factor of 1.03 (Zhang et al., 2015b). 354

355

For the apportionment of AMS-PMF OA factors using 14C data (Zotter et al., 2014), we 356

assume that all OC sources are represented by the six PMF factors and the fNF in NR-PM1 357

was the same as that in PM2.5. The OA mass of each PMF factor and total OA were first 358

converted to OC mass using the OM:OC ratios derived from its MS (OM:OCHOA = 1.29, 359

OM:OCBBOA = 1.5, OM:OCCOA = 1.27, OM:OCCCOA = 1.37, OM:OCLO-OOA = 1.55, 360

OM:OCMO-OOA = 2.01, OM:OCtotal = 1.51). For the OC mass concentration of the AMS 361

factors, the following notations, hydrocarbon-like organic carbon (HOC), biomass 362

burning organic carbon (BBOC), cooking organic carbon (COC), coal combustion 363

organic carbon (CCOC), oxygenated organic carbon (OOC), total organic carbon from 364

AMS (TOCAMS), were adopted in the following sections. An fNF value was assumed a 365

priori for the primary PMF factors HOC, BBOC, COC, and CCOC. The average fNF of 366

OOC is then derived by the equation below: 367

368

fNF_OOC = (TOCNF_AMS − fNF_HOC × HOC − fNF_BBOC × BBOC − fNF_COC × COC − fNF_CCOC 369

× CCOC) / (SV-OOC + LV-OOC) 370

Here HOC is assumed to originate from gasoline and diesel exhaust and contains 371

exclusively of fossil carbon, i.e., fNF_HOC = 0; BBOC is estimated to be originated from 372

biomass burning, i.e., fNF_BBOC = 1; COC is assumed to originate from non-fossil carbon 373

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such as cooking oil and dressing, i.e., fNF_COC = 1; CCOC is estimated to originate from 374

coal combustion, i.e., fNF_CCOC = 0. 375

376

3 Results and discussions 377

3.1 Overview of field study 378

3.1.1 Meteorological conditions 379

Fig. 1 shows the time series of meteorological parameters and PM1 components during 380

the campaign. The measurement site mainly received air masses from northern and 381

northeastern associated with low wind speeds (WS) ranging from 0.6 to 1.1 m s−1 (on 382

daily average: 0.8 ± 0.2 m s−1). The mountains to the north and south of the city could 383

significantly reduce the wind speeds. Air temperature ranged from −5.0 to 6.6 °C 384

(average = 0.6 ± 3.9 °C) for the diurnal variation during the campaign, but had an evident 385

increase after the Chinese New Year (January 31, 2014) (Fig. 1a). No precipitation event 386

occurred during the campaign, and RH was pretty low ranging from 16.8 to 39.5% (on 387

daily average = 27.5 ± 7.4%) for the diurnal variation. Overall, the meteorological 388

conditions during the campaign were much stable and dryer than those during summer 389

2012 (on average: 1.2 ± 0.6 m s−1 for WS and 60 ± 17 % for RH). 390

391

3.1.2 Inter-comparisons 392

The inter-comparisons between AMS vs. SMPS and TEOM are shown in Fig. S3. 393

Comparison between the mass concentration of PM1 and the volume of particle measured 394

by SMPS is tightly correlated (R2 = 0.9) with a slope of 1.48, which represents the 395

average density of bulk particles, assuming that the AMS and the SMPS measure a 396

similar particle population. This value is indeed very close to the estimated PM1 density 397

(1.46) based on the measured particle composition for this study (using density of 1.2 g 398

m-3 for organics, 1.72 g m-3 for NH4NO3, 1.77 g m-3 for (NH4)2SO4, 1.52 g m-3 for NH4Cl 399

and 1.8 g m-3 for BC) (Zhang et al., 2005; Bond and Bergstrom, 2006). The mass 400

concentration of PM1 is also closely correlated (R2 = 0.71) with TEOM PM2.5 401

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concentrations with a slope of 0.73. Similar contribution of PM1 to PM2.5 were also 402

observed in other cities in China during winter (Elser et al., 2016), such as Beijing (0.74 403

during 2011) (Sun et al., 2013b). Note that the actual mass ratio between PM1 and PM2.5 404

should be higher than these values since refractory materials such as crustal components 405

were not measured. 406

407

3.1.3 PM1 composition, variation, and acidity 408

The average mass concentration of PM1 (NR-PM1 + BC) was 57.3 µg m−3 (ranging from 409

2.1 to 229.7 µg m−3 for hourly average) during this study, with 51.2% of organics, 16.5% 410

of nitrate, 12.5% of sulphate, 10.3% of ammonium, 6.4% of BC, and 3.0% of chloride 411

(Fig. 2a). The average mass concentration was more than twice the average value 412

observed during summer 2012 (24.5 µg m−3). All species showed similar day-to-day 413

variation with nitrate being the most significant one (Fig. 1e), suggesting an important 414

local source for nitrate. The mass contributions of PM1 species from low to high PM1 415

concentrations showed an increased contribution for organics (49% to 53%) and nitrate 416

(13% to 18%), but a decreased contribution for sulphate (17% to 11%) and BC (7.3% to 417

5.3%) suggesting somewhat different chemical processes/sources for each species during 418

the haze pollution (Fig. 2b). Specifically, the increased organics was mainly due to the 419

contribution of primary OA (POA) based on PMF analysis (more discussion are given in 420

section 3.5). During the late part of Chinese New Year holiday (February 3 to end of the 421

study), PM1 concentration decreased in association with increased wind speed (~1 m s−1 422

to 2 m s−1). NR-PM1 appeared to be neutralized throughout this study, as indicated by an 423

overall stoichiometric charge balance between the anions (i.e., nitrate, sulphate, and 424

chloride) and the cation ammonium (slope = 0.94, Fig. S4). This result indicates that the 425

inorganic particulate species were mainly present in the forms of NH4NO3, (NH4)2SO4, 426

and NH4Cl in PM1. 427

428

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3.1.4 Size distribution 429

The average chemically-resolved size distributions of NR-PM1 species are shown in Fig. 430

3a. While all components peaked between 400–500 nm, organic aerosol presented a 431

wider distribution than the inorganics and extended to ~250 nm, suggesting the influence 432

of fresh organics (POA, more discussion are given in section 3.4). These features were 433

similar to those found in most urban sites by the AMS. The similar mode size of 434

inorganics and SOA (Fig. 3c) suggested the well internally mixed air mass during the 435

sampling period. The mass contributions of chemicals at the major peak (400–500 nm) 436

were organics (~50%), nitrate (~20%), ammonium (~15%), sulphate (~10%), and 437

chloride (~5%); while the contribution of organics increased with the decreasing of size 438

mode (Fig. 3c). Comparing with the results observed during 2012 summer, the size 439

distributions of aerosol particle during winter were narrower, although the mode sizes of 440

major peaks were similar, indicating highly mixed and aged aerosol particles during 441

winter. Note that chloride also showed a wider distribution which was more similar with 442

organics other than sulphate and nitrate. This was not observed during 2012 summer and 443

could be related with OA emitted from coal combustion and biomass burning during 444

wintertime. Note that chloride also showed a wider distribution which was more similar 445

with organics other than sulphate and nitrate. This was not observed during 2012 summer 446

and could be related with OA emitted from coal combustion and biomass burning during 447

wintertime. 448

449

3.2 Diurnal variations of aerosol species 450

All species show significant diurnal variations during the study suggesting the important 451

local and regional sources of aerosol (Fig. 4). The observed diurnal trends of BC 452

presented two dominant peaks with one at late morning (10:00–12:00) and another at 453

early evening (20:00–22:00). The morning peak did not overlap with the rush hours 454

(7:00–9:00), different than that of summer 2012; the BC mass loading started to increase 455

from 6:00 continuously during morning, and reached maximum between 10:00–12:00 456

and then dropped down after the noon time. Another combustion tracer, carbon monoxide 457

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(CO), also showed the similar morning peak (Fig. 5). This morning peak was likely 458

resulted from the contribution of multiple combustion sources, such as coal combustion, 459

biomass burning, and traffic emission which had different morning peaks (see section 460

3.4), and the formation of inversion layer during winter at Lanzhou which promoted 461

accumulation of air pollutants from enhanced human activities in the morning. This 462

inversion layer frequently formed from night time and diffused after the noon time due to 463

the valley terrain (Zhang et al., 2011b). The temperature profile observed at the suburban 464

Lanzhou (Yuzhong, ~30 km from the sampling site) showed a strong inversion in the low 465

boundary layer during the morning time (Fig. S8). But such influences should be further 466

verified in the future with simultaneous measurements from boundary layer heights. The 467

evening peak of BC could result from increased human activities such as traffic, cooking, 468

and heating coupled with low boundary layer after sunset. Organics had two sharp peaks 469

at the noon time (12:00–13:00) and early evening (19:00–20:00) which correspond to 470

lunch time and dinner time, respectively, indicating the importance of cooking-related 471

emissions of OA. PMF analysis show that cooking-emitted aerosol could contribute up to 472

50% of organics during meal times (section 3.4.3). 473

474

Sulphate presented two peaks with one occurring at the noon time (11:00–14:00) in 475

accordance with the photochemical processes; this peak is narrower than that during 476

summer, likely due to relatively weak photochemical activities. Another minor peak 477

occurred between 20:00–22:00 which was likely due to the lowered boundary layer depth. 478

The significantly higher concentration of sulphate during winter than summer could 479

result from a higher amount of precursor SO2 emission, wintertime hydroxyl radical 480

formation, and the increased aerosol particle surface due to high PM loadings that 481

facilitated the heterogonous conversion of SO2 to sulphate (Yong et al., 2012; Pusede et 482

al., 2015; Zheng et al., 2015). The diurnal pattern of sulphate during winter was similar to 483

that of summer 2012 at Lanzhou and summer 2011 at Beijing, but was different from that 484

of Beijing during winter 2011/2012 where aqueous processing was found to could play 485

an important role (Sun et al., 2013b). Chloride had similar diurnal pattern with sulphate, 486

although the evening peak was more obvious. The major source of hydrochloric acid is 487

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biomass burning, coal combustion and waste combustion (Ianniello et al., 2011). The 488

significant evening peak could be related with these sources coupled with the shallow 489

boundary layer. The high background concentrations of chloride during day and night 490

suggest a persistent emission of hydrochloric acid which could be from the heating 491

factory and power plants. The diurnal pattern of chloride during winter was different 492

from that during summer 2012 which peaked during the night time due to temperature-493

dependent gas-particle partitioning. Nitrate peaked between 12:00–16:00, right after the 494

peak of sulphate. The formation of nitrate during afternoon suggests that nitrate was 495

dominated by the homogeneous photochemical production. Fig. 5 shows the variations of 496

NOx and O3 calculated from data downloaded from one station monitored by the Ministry 497

of Environmental Protection of China, ~3 km southwest of sampling site (Fig. S1a); NO 498

had a morning peak (7:00–10:00) and an evening peak (19:00–21:00) corresponding to 499

rush hours; NO2 increased from 10:00 which formed from NO consumed by O3 and 500

slightly decreased from 14:00 to 18:00 corresponding to the photolysis of NO2 and the 501

formation of nitric acid during afternoon. The diurnal change of NOx (∆NOx) mixing 502

ratio was ~50 ppbv (from 150 to 100 ppbv), while the diurnal change of the sum of ∆O3 503

and ∆NO3− was ~30 ppbv. Considering the higher mixing layer height during afternoon, 504

it seems that nitrate was mainly formed from the photochemical processing of NOx. The 505

diurnal pattern of nitrate during winter was vastly different from that during 2012 506

summer which was mainly controlled by the dynamic of mixing layer and gas-particle 507

partitioning. 508

509

3.3 Bulk characteristics and elemental ratios of OA 510

Table 1 shows the average elemental mass composition and mass contributions of six ion 511

categories to the total organics. Carbon contributed 67% to the organics following by 512

oxygen (23%), hydrogen (9%), and nitrogen (1%); correspondingly, CxHy+ dominated the 513

organics by 59%, following by CxHyO1+ (26%), CxHyO2

+ (10%), HyO1+ (2%), and 514

CxHyNp+ (2%). Compared with the results of 2012 summer, the organics in winter had 515

higher carbon (67% vs. 59%) and CxHy+ content (59% vs. 56%), and lower oxygen 516

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content (23% vs. 26%) (Fig. 6c); this suggests that the organics during winter had a 517

higher fraction of primary compounds than those during summer which was likely due to 518

weaker photochemical activities, lower boundary layer height and more emissions from 519

primary sources. The average O/C of organics, an indicator for oxidation state, was 0.28 520

during this study which was somewhat lower than that of summer 2012 (0.33) (Fig. 6a 521

and b). Photochemical processing of organics during winter appeared to be significantly 522

weaker and shorter than those during summer as shown by the smaller diurnal peak of 523

O/C (Fig. 6d). The diurnal profile of H/C was inversely correlated with that of O/C, and 524

the peaking of organic aerosol concentration usually corresponded to the high H/C ratio 525

and low O/C ratio, indicating the dominant role of primary OA. 526

527

3.4 Source apportionment of OA 528

Source apportionment via PMF with ME2 engine on OA mass spectra resolved six 529

components, i.e., HOA, COA, CCOA, BBOA, LO-OOA, and MO-OOA. Each 530

component has a unique mass spectral pattern, diurnal pattern, and temporary variation 531

which correlated with corresponding tracers such as inorganic species. Two OOA 532

components can be regarded as surrogates of SOA, with MO-OOA for more aged SOA 533

and LO-OOA for fresher SOA; The HOA, BBOA, COA and CCOA components are 534

regarded as POA based on their low O/C ratios and good correlations with primary 535

aerosol tracers (Fig. 7). Comparison with the source apportionment results of summer 536

2012, the organic sources and chemical processes during winter 2013/2014 were more 537

complex due to the multiple primary sources. Detailed discussion of each factor is given 538

in the following subsections. 539

540

3.4.1 HOA 541

HOA factors had been frequently separated from the OA in urban area due to the 542

emission from traffic and/or other fossil combustion activities (e.g., Sun et al., 2011b; Ge 543

et al., 2012). The diurnal pattern of HOA in winter 2013/2014 of Lanzhou shows two 544

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predominant peaks in the morning (6:00–10:00) and evening (20:00–21:00), respectively 545

(Fig. 5). The peaks were mainly associated with the traffic rush hours and low PBL depth 546

before and after sunset. The relatively low concentration during afternoon was probably 547

due to the high PBL depth as shown by the mass concentration variations of BC. The 548

correlation between HOA and BC was high (R2 = 0.64, Fig. 7f and Table 2), as a big 549

fraction of BC has been thought to emit from traffic activities. The minimum of HOA 550

concentration, which typically occurred during afternoon or middle night, was still up to 551

~2 μg m−3 suggesting a high background of HOA which is likely due to the stagnant air 552

condition unfavourable for the diffusion of aerosol. The size distribution of HOA showed 553

a mode size of ~200 nm (Fig. 3b) corresponding to the primary emitted aerosol 554

behaviours and HOA could account for ~25% mass of aerosols between 100-300nm (Fig. 555

3c). The average concentration of HOA during 2013/2014 winter was 2.9 μg m−3 556

accounting for 9.8% of organics (Fig. 8a). This concentration was higher than that of 557

2012 summer in Lanzhou (2.9 vs. 1.8 μg m−3) likely due to the lower PBL during winter 558

and stagnant air conditions. The mass contribution from HOA is similar to the result of 559

2013 winter at Beijing (9%) which was also the lowest contributor to the total OA (Sun et 560

al., 2013b; Zhang et al., 2014), probably due to more modern vehicles were used in the 561

recent years. 562

563

3.4.2 BBOA 564

BBOA component had been widely observed in USA and European countries during 565

winter due to the traditional wood burning for residential heating (Alfarra et al., 2007). 566

The BBOA component is thought to be less important in China because coal is the major 567

fuel during winter. BBOA could be an important component in China during some 568

special periods. For example, Zhang et al. (2015a) identified a BBOA factor in urban 569

Nanjing, southeast of China, during harvest seasons of summer and autumn because of 570

the burning of straw. The BBOA component has also been identified in some regions in 571

China where the coal resource is scarce. For example, Du et al. (2015) separated a BBOA 572

factor at a rural site of the northern Tibetan Plateau due to the widely usage of cow dung 573

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cake for heating in this region. The BBOA component has also been identified during 574

winter in cities in southern China because of rich wood resource in these regions (He et 575

al., 2011; Huang et al., 2011; Huang et al., 2013). To our knowledge, only three recently 576

papers have reported the identification of a BBOA factor during winter using online 577

measurement in an urban area of northern China (Elser et al., 2016; Hu et al., 2016; Sun 578

et al., 2016). Although the high contribution of non-fossil carbonaceous aerosol was 579

found (Zhang et al., 2015b) and the mass spectra of organic in other cities (such as 580

Beijing) during winter have also significant contributions from m/z 60 and 73 (Sun et al., 581

2013b; Zhang et al., 2014), it is difficult to separate the BBOA using general PMF 582

because of its similar temporal variation with CCOA, such as diurnal pattern (Fig. 4). 583

BBOA contributions presented a clear periodic change (Fig. 1), and on average were high 584

during night time and low during daytime (Fig. 5). This trend is consistent with 585

conventional usage of biomass for heating. The time series of BBOA was also closely 586

correlated with BC and chloride (Table 2) due to significant emission of these species 587

from biomass burning. The average mass concentration of BBOA was 3.2 μg m−3, on 588

average contributing 10.8% of the total OA mass for the entire study (Fig. 8a), but could 589

reach up to ~20% during night and down to less than 5% during afternoon (Fig. 8b). This 590

average concentration was close to the results observed at southern Chinese cities such as 591

Jiaxing (~3.9 μg m−3) (Huang et al., 2013), Kaiping (~1.36 μg m−3) (Huang et al., 2011) 592

and Shenzhen (~5.2 μg m−3) (He et al., 2011). 593

594

The size distribution of BBOA peaked at ~400nm which is close to accumulation mode 595

(Fig. 3b). This feature could be due to internal mixing or coagulation of particles. The 596

O/C ratio of BBOA is 0.24, which is consistent with the primary BBOA feature (Ortega 597

et al., 2013). The similar O/C and the dominance of an accumulation mode in the size 598

distribution of BBOA were also observed during winter in Fresno, a major city in the 599

Central Valley of California, USA (Ge et al., 2012; Young et al., 2015). 600

601

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3.4.3 COA 602

The COA component has been widely identified in urban AMS studies and observational 603

results by other instruments recently, and it is regarded as important source of OA in 604

urban areas (Abdullahi et al., 2013 and references therein). The MS of COA in this study 605

had a major contribution from CxHy+ ions (81.6%) with also an important contribution 606

from CxHyO1+ ions (14.7%), similar as those in HOA (81.0% and 13.0%) (Fig. S9). In 607

comparison with the HOA spectrum, COA had a higher m/z 55 to 57 ratio (2.0 vs. 0.8) 608

(Fig. 7) which had been postulated as a significant indicator for COA (Sun et al., 2011b; 609

Mohr et al., 2012). In the V-shape plot defined by Mohr et al. (2012), which uses f55 vs. 610

f57 after subtracting the contributions from factors of OOA, CCOA, and BBOA (denoted 611

as OOA_CCOA_BBOA_sub, i.e. f55OOA_CCOA_BBOA_sub and f57OOA_CCOA_BBOA_sub), the 612

data can be clearly represented with ones during morning close to HOA line and ones 613

during meal times close to COA line (Fig. S10). The MS of COA is highly similar to that 614

of summer 2012 observation (R2 = 0.76, slope = 0.99, Fig. S11) which was found to 615

resemble closely the COA MS from other locations (Xu et al., 2014). In fact, the COA 616

components were found to be associated with heating of cooking oils rather than burning 617

of meat/food itself, and indeed the COA mass spectra from cooking of different dishes 618

were highly similar (He et al., 2010). The O/C and H/C ratios of COA were 0.07 and 1.73, 619

respectively, suggesting its feature as POA. This O/C ratio was slightly lower (0.07 vs. 620

0.11) and the H/C was slightly higher than that of 2012 summer (1.73 vs. 1.69). The size 621

distribution of COA was also peaking between 100–200 nm similar to that of HOA (Fig. 622

3b). The diurnal variation of COA displayed two predominant peaks standing out at lunch 623

time (12:00–13:00) and dinner time (19:00–20:00), respectively (Fig. 5), and a small 624

breakfast peak (~8:00). This pattern was consistent with that of summer 2012 (Fig. 4) 625

which resulted from the consistent routine life during winter and summer. The enhanced 626

COA concentration at dinner time might be mainly due to the low PBL height and the 627

activity of a formal meal with more attendants and longer time than that of lunch. The 628

temporal variation correlated tightly with C6H10O+ (R2 = 0.96, Fig. 7d) which has been 629

reported as the high resolution mass spectral markers for ambient COA (Sun et al., 2011b; 630

Ge et al., 2012). 631

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632

The average contribution of COA to organics was 20.2% (~10–50%) (Fig. 8a) with an 633

average mass concentration of 5.92 μg m−3 which was much higher than those of HOA 634

and BBOA. This contribution is similar to those in Beijing during winter (average 19% of 635

OA with a range of 16–30%) (Sun et al., 2013b), Fresno (~19% of OA) (Ge et al., 2012), 636

Barcelona (17% of OA) (Mohr et al., 2012), and Paris (11–17%) (Crippa et al., 2013). 637

This high fraction indicates that COA is an important local source of OA in Lanzhou 638

regardless of clear or hazy periods (section 3.5). 639

640

3.4.4 CCOA 641

A CCOA component had been identified in this study with its MS similar to the OA from 642

coal burning in lab study (Dall'Osto et al., 2013). The MS of CCOA had high signals at 643

m/z 41, 43, 44, 55, 57, 69, 91 and 115 (dominated by CxHy+ ions) (Fig. 7i) (Elser et al., 644

2016). CxHy+ ions in total account for 69.9% of CCOA MS, following by CxHyO1

+ 645

(19.2%) and CxHyO2+ (7.1%). The fractions of CxHy

+ and CxHyO1+ were similar with 646

those in HOA MS (Fig. S9), but the CCOA MS had high signal intensity at m/z 44 647

(mainly CO2+) which is different from that of HOA (Fig. 7). This high CO2

+ fraction was 648

also observed in CCOA MS in Changdao island in China during winter (Hu et al., 2013). 649

Wang et al. (2015) suggested this high CO2+ signal is from the oxidative transformation 650

of the pyrolysis products during coal burning. Zhang et al. (2008) reported that 48–68% 651

of particulate organic matter from coal combustion aerosol is found in the form of 652

organic acids. The O/C ratio is thus higher than that of HOA (0.20 vs. 0.10) with a lower 653

H/C ratio (1.54 vs. 1.86). The CCOA also locates in a lower left position in the triangle 654

plot defined by Ng et al. (2010) (Fig. 9a). These features indicate CCOA is a POA factor 655

but is a little more oxygenated than HOA. The time-dependent concentrations of CCOA 656

correlated with BC (R2 = 0.59) and chloride (R2 = 0.49) which also correlated well with 657

HOA and BBOA (Table 2). Note that although the similar temporal variations between 658

BBOA and CCOA, the significant differences between their MS (in particular, m/z 91) 659

suggested their different origins. In addition, high PAH signals had been observed in the 660

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CCOA MS, and this is consistent with previous results that the coal combustion could be 661

a dominate source of PAHs in China (Okuda et al., 2006; Sun et al., 2016).The CCOA 662

mass loading remained high from 20:00 to 10:00, slowly decreased to a minimum at 663

16:00, and then increased from 16:00 to 20:00 (Fig. 5). This diurnal pattern was similar to 664

that of BBOA which were all mainly emitted from heating. The slower decreasing rate 665

during morning and increasing rate during late afternoon for CCOA than those of BBOA 666

could related with wide usage of coal, such as cooking and power plants. In our summer 667

2012 observation, we also observed OA signals from coal combustion which suggest 668

persistent emitted during the whole year in Lanzhou. The size distribution of CCOA 669

peaked ~450 nm (Fig. 3b), similar with that of BBOA. 670

671

The average CCOA mass concentration was 6.4 μg m−3, accounting for 22.0% of total 672

OA mass (Fig. 8a). The mass fraction of CCOA could reach to ~30% of OA during night 673

and decreased to 3% during afternoon (Fig. 8b). This indicates that CCOA was an 674

important OA component similar as that in Beijing OA (15–55%) (Zhang et al., 2014; 675

Elser et al., 2016), but its mass fraction of PM2.5 (~9%) was at the low end of the values 676

observed at Beijing and Xi'an (9–21%) (Huang et al., 2014). 677

678

3.4.5 LO-OOA and MO-OOA 679

Two or more OOA components are commonly separated by PMF in urban areas which 680

correspond to fresh SOA and aged SOA (Jimenez et al., 2009), and the MS of SOA 681

factors all have predominant contributions at m/z 43 and 44. The MS of fresher SOA such 682

as LO-OOA has higher contribution at m/z 43 (mainly C2H3O+, accounting for 74% of 683

m/z 43 in this study), while aged SOA such as MO-OOA has higher signal at m/z 44 684

(mainly CO2+, accounting for 99% of m/z 44 in this study). The contribution of CxHyO1

+ 685

in LO-OOA was 36.8% followed by CxHy+ (48.0%), CxHyO2

+ (10.3%), HyO1+ (1.6%), 686

CxHyNp+ (2.8%), and CxHyOzNp

+ (0.5%) (Fig. S9). The O/C ratio of LO-OOA was 0.33 687

and H/C was 1.47 consistent with fresh SOA. The MS of MO-OOA was comprised of 688

25.3% of CxHyO2+, 35.7% of CxHyO1

+, 30.1% of CxHy+, 6.7% of HxO1

+, 1.8% of CxHyNp+, 689

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25

and 0.4% of CxHyOzNp+ (Fig. S9). The O/C and H/C ratios of MO-OOA were 0.80 and 690

1.14, respectively. These results indicate that the atmospheric oxidation capacity during 691

winter was still somewhat strong. The positions of LO-OOA and MO-OOA in triangle 692

plot of fCO2+ vs. fC2H3O

+ are situated in the space of triangle plot with MO-OOA at the 693

upper left corner (Fig. 9b) and LO-OOA at the lower right space, respectively, suggesting 694

the different oxidation degree of OOA factors. The MS of LO-OOA and MO-OOA were 695

similar with those of summer 2012 (R2 = 0.95 for MO-OOA and R2 = 0.80 for LO-OOA, 696

Fig. S11). Note that the CxHy+ ions in LO-OOA were mainly from by m/z 39, 41, 91 and 697

115 (Fig. 7h), which were also found to be enriched in coal combustion organic aerosols. 698

This feature is similar to that of summer 2012, potentially suggesting that part of LO-699

OOA was from further oxidation of CCOA. 700

701

The temporal variations of LO-OOA and MO-OOA were highly correlated with 702

secondary inorganic species: LO-OOA vs. sulphate (R2 = 0.71) and MO-OOA vs. nitrate 703

(R2 = 0.71) (Fig. 7a and b, Table 2). These patterns are somewhat contradictory to 704

previous AMS findings that LO-OOA typically correlates better with nitrate due to their 705

similar semi-volatile characteristics while MO-OOA tends to correlate better with 706

sulphate as they are both low-volatility species. These correlations were indeed observed 707

during the summer study of 2012 (Xu et al., 2014). The behaviours of the two OOA 708

factors during this study were likely due to the low air temperature and low RH 709

conditions which favoured nitrate formation primarily through photochemical reactions. 710

This phenomenon was also observed in winter time of Beijing (Sun et al., 2013b). 711

712

The diurnal variation profiles of LO-OOA and MO-OOA all showed one bump with the 713

LO-OOA peaking between 11:00–14:00 and MO-OOA peaking between 12:00–18:00, 714

suggesting the importance of photochemical processes for both OOA factors. The size 715

distribution of the OOA (LO-OOA + MO-OOA) had a mode size of ~550 nm (Fig. 3b) 716

reflecting the feature as SOA. This size mode is slightly bigger than those of OOA in 717

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26

other studies such as Fresno (460 nm) and Lanzhou summer 2012 (~450 nm) likely due 718

to the high concentration of gas precursors and longer lifecycle of aerosol during winter. 719

720

The mass concentrations of LO-OOA and MO-OOA were 6.5 and 4.4 µg m−3 with the 721

mass contributions of 22.3% and 14.9% to OA, respectively (Fig. 8a). These 722

contributions were lower than those during summer 2012 in Lanzhou (27% for LO-OOA 723

and 32% for MO-OOA) especially for MO-OOA, likely due to the relative weak solar 724

radiation during winter and more primary sources in winter. The diurnal total 725

contribution of OOA (LO-OOA + MO-OOA) varied between 20%–60% (Fig. 8b), 726

suggesting the importance of SOA in the air pollution throughout the day at Lanzhou. 727

728

3.5 Primary and secondary OA 729

As shown in Fig. 2b, the mass fraction of organics increased with the increase of PM1 730

concentration, so it is important to know the relative contributions of primary and 731

secondary OA components during the pollution periods. Fig. 10a shows the scatter plot of 732

SOA (= LO-OOA + MO-OOA) and POA (= HOA + BBOA + COA + CCOA) during this 733

study. It is clear that POA and SOA show relative tight correlation during the periods of 734

POA less than ~15 µg m−3 associated with low mass fractions of OA. When POA and 735

OA fraction increased significantly, POA and SOA show almost no correlation, 736

indicating the importance of POA in the severe aerosol pollutions in Lanzhou during 737

winter. This is different than the observation from summer 2012, during which SOA had 738

a stable contribution to PM1 (Fig. 10b), due to more complex POA sources and larger 739

contributions from these sources to PM1 mass loading during winter compared to 740

summer. This is even more evident when comparing each POA factor with OA (Fig. 11). 741

The COA had the biggest contribution to the increased organics can explained 51% of the 742

increase of organics, followed by CCOA (19%). The components of HOA and BBOA 743

also had positive contributions to the increase of PM1 mass. However, both OOA 744

components had negative slopes with organics with LO-OOA being the major one. The 745

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27

phenomenon of POA dominating during haze periods is different from the results in other 746

cities in China (Huang et al., 2014). For example, Elser et al. (2016) found significant 747

increased contribution from SOA and secondary inorganic aerosol during haze periods in 748

2013/2014 winter in Xi'an and Beijing. This is likely due to the higher RH values in the 749

eastern China which is more favourable for the aqueous-phase production of SOA. 750

Indeed, Sun et al. (2013a) observed significant increase of secondary inorganic aerosol 751

during high RH periods in Beijing. 752

753

The average contribution of POA to organics decreased from 63.0% to 39.3% during 754

Chinese New Year festival of 2014 (Fig. 1) due to the reduced primary aerosol sources 755

(many restaurants were closed during the holiday of Chinese New Year) such as HOA 756

(9.8% to 3.3%), COA (20.2% to 11.6%), CCOA (22.0% to 15.4%), and BBOA (10.8% to 757

9.0%). This is an indication that control of cooking activities and traffic emissions in this 758

residential area may be effective strategies for air quality improvement during winter. 759

760

3.6 Fossil and non-fossil OC 761

OC measured by OC/EC analyser on two filters (OCfilter) and corresponding AMS 762

(OCAMS) online measured results are shown in Fig. 12a. The average ratio of 763

OCAMS/OCfilter was ~1.5 for these two filters likely due to the analytical uncertainties of 764

different instruments (30% for AMS and 20% for OCfilter), which was also observed in 765

other studies (Zotter et al., 2014). The data from the 14C measurement for the filter 766

samples are listed in Table S1. The total average of fNF in these four filters was 55 ± 3%, 767

with 54% and 57% for filters during Jan. 15 and Jan. 23, respectively. Comparison with 768

other studies, the average fNF value in this study was lower than those in Xi'an (63%) and 769

Guangzhou (65%), and higher than those in Beijing (42%), while similar with those in 770

Shanghai (51%) during 2012/2013 winter (Zhang et al., 2015b). Combining with the fNF 771

value (the total average of fNF for the total average AMS results) and the contributions of 772

fossil (F) POC (HOC and CCOC) and non-fossil (NF) POC (BBOC and COC), the fF and 773

fNF for SOC could be obtained (Fig. 12b). The average fF and fNF for POC and SOC are 774

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28

summarized into Fig. 13. The fF and fNF for POC during Jan. 15 were 50% and 50%, 775

while for SOC were 32% and 68%. The fF and fNF for POC during Jan. 23 were 37% and 776

63%, while for SOC were 56% and 44%. For all AMS data, the fF and fNF in POC were 777

50% and 50%, while for SOC were 34% and 66%. The F-POC during Jan. 15 and Jan. 23 778

were comprised by 15% and 16% HOC and 35% and 21% CCOC, respectively, and NF-779

POC by 18% and 13% BBOC and 32% and 50% COC, respectively. For all AMS data, 780

the F-POC was comprised by 17% HOC and 33% CCOC, and NF-POC by 16% BBOC 781

and 34% COC. 782

783

3.7 Evolution of OA and relationship between odd oxygen and SOA 784

The evolution of OA chemical composition upon aging has been an important subject 785

which is used to understand the formation of SOA. The methods to characterize this 786

evolution include the application of several specific diagrams, such as the AMS triangle 787

plot (f44 vs. f43 or fCO2+ vs. fC2H3O

+) (Ng et al., 2010) and Van Krevelent plot (H:C vs. 788

O:C) (Heald et al., 2010). In the plot of f44 vs. f43 of this study (Fig. 9a), the data 789

distributed in a narrow space and move up vertically in the triangle space suggesting 790

significant increasing in f44. The data from the low (night time) to the high (afternoon 791

time) f44 value corresponded to the evolution of the photo radiation intensity suggesting 792

the photochemical processes. In the plot of fCO2+ vs. fC2H3O

+ (Fig. 9b), most of data 793

moved out of triangle space because of the high contribution of C3H7+ at m/z 43, 794

especially for data during night time. fCO2+ and fC2H3O

+ both increased before the noon 795

time, after that fC2H3O+ stopped at ~0.06 and fCO2

+ kept increase likely suggesting the 796

evolution of LO-OOA to MO-OOA. In comparison to the results in summer 2012, the 797

data in winter were more concentrated in the triangle space suggesting air masses with 798

similar source contribution during winter. The winter data in the Van Krevelen diagram 799

follows a slope of −0.8 (Fig. 14a) which suggest that SOA formation chemistry was a 800

combination of carboxylic acid and alcohol/peroxide formation (−1 to −0.5). This slope is 801

higher than that observed at Changdao (−0.6, rural site) in China during winter 802

suggesting the less oxidation state of our data. 803

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29

804

In order to understand the possible sources of oxygenated OA, we also compared the 805

diurnal variations between MO-OOA and Ox (Fig. 14b). Both Ox and OOA are products 806

of photochemical reactions and the comparison between Ox and OOA can offer insight 807

into the formation of OA due to the dependence of the ratio on the VOC species 808

(Herndon et al., 2008), assuming aqueous processing and night time oxidation for OOA 809

were less important, such as during this study due to the low RH. High SOA vs. Ox slopes 810

were observed (larger than 0.12 µg m−3 ppb−1) where aromatic VOC dominated the 811

photochemical processing, while a low slopes (~0.03 µg m−3 ppb−1) were observed where 812

alkene VOCs dominated the photochemical processing (Wood et al., 2010; Hayes et al., 813

2013). Fig. 14b shows the scatter plot between Ox and MO-OOA and sized by the mass 814

concentration of BBOA. Ox and MO-OOA showed tight correlation (R2 = 0.95) with a 815

slope of 0.11 µg m−3 ppb−1. This result is similar with that found in Beijing during 816

wintertime, which has suggested that semivolatile VOCs (e.g., PAHs) could be the 817

primary precursor of OOA (Hu et al., 2016). Several studies suggested that aromatic 818

VOC is dominant among VOCs in northern China (Zhang et al., 2015c) and can be 819

important contribution for SOA production (Liu et al. 2012). We also did correlation 820

between LO-OOA and Ox, and found the different synchronization of LO-OOA and Ox 821

(Fig. S12). It seems LO-OOA varied two to three hours earlier than Ox, likely suggesting 822

other origination for LO-OOA such as down mixing of mixing-layer aerosol, which is a 823

popular phenomenon in the mountain-valley city (Chen et al., 2009). 824

825

4 Conclusions 826

In order to understand the sources and chemical processes of the air pollution during 827

winter in Lanzhou, a field study was conducted at an urban site of Lanzhou during 828

January 10 – February 4, 2014 using a suit of on-line instruments. The results show that 829

the average mass concentration of PM1 (NR-PM1 + BC) was 57.3 µg m−3 (ranging from 830

2.1 to 229.7 µg m−3 for hourly averages), with 51.2% of organics, 16.5% of nitrate, 831

12.5% of sulphate, 10.3% of ammonium, 6.4% of BC, and 3.0% of chloride. This mass 832

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30

concentration was about two times higher than that during summer 2012 in Lanzhou, 833

however, the mass loading levels and chemical compositions were similar to those 834

observed in Beijing during winter. The mass concentration of nitrate and organics 835

increased with the increase of PM1 loading, while sulphate decreased, indicating the 836

importance of OA and nitrate during severe air pollution. The size distributions of all the 837

species displayed a moderate size at 400–500 nm, suggesting that aerosol particles were 838

largely internally mixed during winter. All species presented significant diurnal 839

variations. BC had two peaks at 10:00–12:00 and 20:00–22:00, respectively. Further 840

analysis indicated that the first peak was resulted from the contribution of multiple 841

combustion sources and could be related with the variations of the boundary layer heights 842

during morning which accumulated the air pollutants from early morning and until the 843

break-up at around noon time (such influences should be further verified in the future 844

with simultaneous measurements from boundary layer heights). The evening peak of BC 845

was related to human activities such as traffic and coal combustion coupled with the 846

shallow PBL. OA presented two peaks corresponding to lunch and dinner time 847

suggesting cooking to be an important source. Sulphate peaked during the noon time 848

(11:00–14:00) indicating the importance of photochemical processes. Nitrate presented 849

an afternoon peak (12:00–16:00) which indicate the photochemical processing of NOx. 850

The diurnal pattern of nitrate during winter time was significant different from that 851

during summer 2012 which was thought mainly from the mixing down of aloft residual 852

layer. PMF analysis of organic mass spectrum with the ME-2 engine identified six 853

organic aerosol sources: i.e., HOA, BBOA, COA, CCOA, LO-OOA, and MO-OOA. 854

POA, which includes HOA, BBOA, COA, and CCOA, accounted for 63% of OA mass 855

and showed an increased in concentration with the increase of PM1 loading. This is an 856

indication that POA emission was one of the main reasons for the occurrence of heavy air 857

pollution episodes. The temporal profile of MO-OOA tightly correlated with that of 858

nitrate, while those of LO-OOA with sulphate correlated. This observation was different 859

than those observed during other studies and during summer at Lanzhou, indicating the 860

importance of photochemistry for nitrate during winter in Lanzhou due to cold air 861

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31

temperature and low RH conditions. 14C analysis of OOC indicated that 66% of the SOC 862

was formed from non-fossil source. 863

864

Acknowledgements 865

The authors thank their colleagues for continuing support and discussion. This research 866

was supported by grants from the Chinese Academy of Sciences Hundred Talents 867

Program, the Key Laboratory of Cryospheric Sciences Scientific Research Foundation 868

(SKLCS-ZZ-2015-01), the National Natural Science Foundation of China Science Fund 869

for Creative Research Groups (41121001, 21407079, 91544220), and the Chinese 870

Academy of Sciences Key Research Program (KJZD-EW-G03). 871

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32

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41

Exposure levels, source implications and health risks, Sci. Total. Environ., 511, 1241 792-800, doi:10.1016/j.scitotenv.2015.01.003, 2015c. 1242

Zhao, X. J., Zhao, P. S., Xu, J., Meng, W., Pu, W. W., Dong, F., He, D., and Shi, Q. F.: 1243 Analysis of a winter regional haze event and its formation mechanism in the 1244 North China Plain, Atmos. Chem. Phys., 13, 5685-5696, doi:10.5194/acp-13-1245 5685-2013, 2013. 1246

Zheng, G. J., Duan, F. K., Su, H., Ma, Y. L., Cheng, Y., Zheng, B., Zhang, Q., Huang, T., 1247 Kimot, T., Chang, D., Poschl, U., Cheng, Y. F., and He, K. B.: Exploring the 1248 severe winter haze in Beijing: the impact of synoptic weather, regional transport 1249 and heterogeneous reactions. Atmos. Chem. Phys., 15(6), 2969-2983 1250 doi:10.5194/acp-15-2969-2015, 2015. 1251

Zheng, M., Salmon, L. G., Schauer, J. J., Zeng, L., Kiang, C. S., Zhang, Y., and Cass, G. 1252 R.: Seasonal trends in PM2.5 source contributions in Beijing, China, Atmos. 1253 Environ., 39, 3967-3976, doi:10.1016/j.atmosenv.2005.03.036, 2005. 1254

Zotter, P., El-Haddad, I., Zhang, Y., Hayes, P. L., Zhang, X., Lin, Y.-H., Wacker, L., 1255 Schnelle-Kreis, J., Abbaszade, G., Zimmermann, R., Surratt, J. D., Weber, R., 1256 Jimenez, J. L., Szidat, S., Baltensperger, U., and Prévôt, A. S. H.: Diurnal cycle of 1257 fossil and nonfossil carbon using radiocarbon analyses during CalNex, Journal of 1258 Geophysical Research: Atmospheres, 119, 6818-6835, 1259 doi:10.1002/2013JD021114, 2014. 1260

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42

1261 Table 1 Comparison of the composition of category ions and elemental composition of 1262

OA between winter 2013/2014 and summer 2012. 1263

1264

1265

Table 2 Coefficient of determination (R2) between time series of OA factors and other 1266

aerosol species. 1267

R2 HOA BBOA COA CCOA LO-OOA

MO-OOA

POA* SOA*

BC 0.64 0.67 0.24 0.59 0.20 0.06 0.64 0.16

PAH 0.40 0.64 0.25 0.58 0.02 0.00 0.61 0.01

Sulphate 0.35 0.24 0.17 0.22 0.71 0.34 0.32 0.64

Nitrate 0.19 0.04 0.15 0.02 0.74 0.71 0.16 0.85

Chloride 0.52 0.52 0.19 0.49 0.45 0.13 0.50 0.35

Sulphate + Nitrate 0.27 0.10 0.18 0.07 0.81 0.62 0.23 0.85

Sulphate + Nitrate + Chloride 0.35 0.18 0.19 0.15 0.77 0.52 0.32 0.77

* POA = HOA + BBOA + COA + CCOA, SOA = LO-OOA + MO-OOA 1268

1269

Category Ions

Winter 2014

Summer 2012

CxHy+ 59% 56%

CxHyO1+ 26% 27%

CxHyO2+ 10% 11%

CxHyNp+ 2% 3%

CxHyNpOz+ 0 1%

HyO1+ 2% 2%

Elemental composition

C 67% 59%

H 9% 7%

O 23% 26%

N 1% 1%

Page 43: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

43

1270 1271 Fig. 1 Summary of meteorological and aerosol species data. (a) air temperature (T) and 1272

relative humidity (RH), (b) wind speed (WS) colored by wind direction (WD), (c) NOx 1273

and visibility, (d) mass concentration of PM1 species, (e) the mass contribution of PM1 1274

species (BC is from aethalometer measurement), and (f) the mass contribution of organic 1275

components to organic aerosol. Note that BC is from aethalometer measurement. 1276

1277

200

100

0

10

0M

ass conc. (µ

g m-3)

100

50

0

% o

f P

M1

100

50

0

% o

f Org

1/11 1/14 1/17 1/20 1/23 1/26 1/29 2/1 2/4

Date (BJT: UTC+8)

10

0

-10

80

40

0

RH

(%)

300

0NO

x (p

pbv)

40

20

0

20

0

200

0

PM

1 (µg m

-3)

40

20

0

Vis. (km

)

3210

WS

Chinese New Year Holiday

Mas

s co

nc.

(µg

m-3

) Cl-

BC

T (

°C)

2014

(a)

(d)

(e)

(b)

(c)

SO42-

NO3-

NH4+

Org

250

0

WD

(°)(m s

-1)

(f) MO-OOALO-OOACOACCOABBOAHOA

Page 44: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

44

1278

1279 1280 Fig. 2 The average mass contribution of PM1 (= NR-PM1 + BC) species (a) during the 1281

whole sampling period and (b) as a function of the PM1 mass concentration (µg m−3) bins 1282

(left). The right axis in (b) shows the accumulated data number in each bin. The organics 1283

were decomposed into primary oganic aerosol (POA) and secondary organic aerosol 1284

(SOA) using PMF (section 3.4). 1285

1286

100

80

60

40

20

0Mas

s p

erc

enta

ge

(%

)

<20

20 - 4040 - 6

060 - 8

0>80

Mass conc. (µg m-3

)

30

20

10

0

% o

f total nu

mbe

r

6.4%

3.0%

10.3% 16.5%

12.5%

32.2% 18.9%

BC Chl

NH4+

NO3-

SO42-

OrgPOA SOA

PM1: 57.3 µg m-3(a)

(b)

Page 45: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

45

1287

Fig. 3 The size distributions of (a) NR-PM1 species, (b) organic components, and mass 1288

contribution of all species to NR-PM1. 1289

1290

20

16

12

8

4

0

dM/D

log

Dva

g m

-3)

4 5 6 7 8100

2 3 4 5 6 7 81000

100

80

60

40

20

0

Mas

s F

ract

ion

(%

)

1002 3 4 5 6 7 8

1000Dva (nm)

30

20

10

0

dM

/Dlo

gDva (µ

g m

-3)

6

4

2

04 5 6 7 8

1002 3 4 5 6 7 8

1000

(a)

(b)

(c)

OrgSO4

2- (x 4)

NO3- (x 2.5)

NH4+ (x 3)

Cl- (x 10)

Total

HOABBOACCOACOAOOA

Page 46: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

46

1291

Fig. 4 The diurnal variation of PM1 species during winter 2013/2014 and summer 2012. 1292

1293

1294

6

4

2

0

Ma

ss C

onc

. (µ

g m

-3)

40

20

012

8

4

0

1612

840

8

4

0

3

2

1

0

8

4

0

12

8

4

0

4

2

0

20

10

06

4

2

0

24201612840Hour of Day

1086420

24201612840

OrgBC

SO4-

NO3-

NH4+

Chl

Winter 2014 Summer 2012

MO-OOA LV-OOA

HOA COA

BBOA CCOA

40

20

0

24201612840Hour of Day

200

100

0

Ma

ss C

onc

. (p

pb)

200

100

0

40302010

03

2

1

0

60

40

20

0

24201612840

x 5

NO2

NO

NOx O3

CO

SO2

Winter 2014 Summer 2012

Page 47: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

47

Fig. 5 The diurnal variations of gas species downloaded from MEP-China station during 1295

winter 2013/2014 and summer 2012. 1296

1297

1298

Fig. 6 The average HR-MS and elemental ratios of organics for (a) this study, (b) summer 1299

2012, (c) the HR-MS difference between this study and summer 2012, and (d) the 1300

diurnal variations of elemental ratios and odd oxygen (Ox = NO2 + O3). 1301

1302

10

8

6

4

2

0120110100908070605040302010

O/C = 0.33, H/C = 1.49N/C = 0.011, OM/OC = 1.58

0.6

0.5

0.4

0.3

0.2

O/C

Rat

io

242220181614121086420Hour of Day (BJT: UTC+8)

1.6

1.5

1.4

H/C

Ratio

100806040200

Ox (p

pbv)

2012 summer O/C

10

8

6

4

2

0120110100908070605040302010

O/C = 0.28, H/C = 1.55N/C = 0.011, OM/OC = 1.51

-4

-2

0

2

120110100908070605040302010m/z (amu)

CxHy+ CxHyO1

+ CxHyO2+

HyO1+ CxHyNp

+CxHyOzNp

+

(a)

(b)

(c)

% o

f to

tal s

ign

al

Winter - Summer

Winter

Summer

(d)

Page 48: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

48

1303

Fig. 7 The PMF results of time series (a – f) and HR-MS (g – l) for each component. The 1304

temporal variations of different tracers are also present for supporting each component. 1305

1306

1307

Fig. 8 (a) The average mass concentration of organics and mass contributions of organic 1308

components to organics, and (b) the diurnal variations of organic components and 1309

organics. 1310

1311

16

8

0

1/11 1/14 1/17 1/20 1/23 1/26 1/29 2/1 2/4

Date (BJT)

16

8

0

3020100

80

40

0

20

10

0

3020100

151050

BC

0.4

0.2

0.0

C2 H

4 O2

+

0.2

0.1

0.0

C6 H

10 O

+

20

10

0

Ch

lorid

e

3020100

Su

lfate

40

20

0

Nitra

te

Mas

s C

on

c. (

µg

m-3

)

2014

(a)

(b)

(c)

(d)

(e)

(f) 12840

120110100908070605040302010

m/z (amu)

8

4

0

12840

12840

20

10

0

8

4

0

HOAO/C = 0.10, H/C = 1.86, N/C = 0.009, OM/OC = 1.29

BBOAO/C = 0.24, H/C = 1.55, N/C = 0.023, OM/OC = 1.48

LO-OOAO/C = 0.33, H/C = 1.47, N/C = 0.016, OM/OC = 1.58

COAO/C = 0.07, H/C = 1.73, N/C = 0.003, OM/OC = 1.24

MO-OOAO/C = 0.80, H/C = 1.14, N/C = 0.016, OM/OC = 2.18

CCOAO/C = 0.20, H/C = 1.54, N/C = 0.008, OM/OC = 1.41

% o

f to

tal

CxHy+ CxHyO1

+ CxHyO2

+ HyO1

+

CxHyNp+CxHyOzNp

+

(g)

(h)

(i)

(j)

(k)

(l)

100

80

60

40

20

0Mas

s P

erce

nta

ge (

%)

242220181614121086420

Hour of Day (BJT: UTC+8)

60

40

20

0

Org. (µ

g m-3)

14.9%

22.3%

22.0%

20.2% 10.8% 9.8%

(a)

(b)

HOABBOACOACCOALO-OOAMO-OOA

Org.: 29.3 (µg m-3

)

Page 49: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

49

1312

Fig. 9 Scatterplots of (a) f44 vs. f43 and (b) fCO2+ vs. fC2H3O

+. The cross dots correspond 1313

to measured OA data points are colored by time of the day. The corresponding values of 1314

the six OA factors identified in this study are also shown. 1315

1316

0.3

0.2

0.1

0.0

f44

(m

/z4

4/O

rg)

0.20.10.0f43 (m/z43/Org)

HOACOA

LO-OOA

MO-OOA

BBOA

CCOA

00:0006:0012:0018:00

Tim

e o

f Da

y (BJT

)

0.3

0.2

0.1

0.0

f CO

2(CO

2+/O

rg)

0.20.10.0fC2H3O

(C2H3O+/Org)

MO-OOA

LO-OOA

HOACOA

CCOA

BBOA

(a)

(b)

Page 50: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

50

1317

1318

1319 Fig. 10 The scatter plot of SOA and POA colored by the ratio of Org/PM1 and sized by 1320

the mass concentration of PM1 for (a) winter 2013/2014 and (b) summer 2012. 1321

1322

(a)

(b)

20

15

10

5

0

SO

A (

µg

m-3

)

806040200POA (µg m

-3)

R2 = 0.1

0.80.70.60.50.40.3

Org/P

M1

1:1 line

PM1 (µg m-3

)30 100

14

12

10

8

6

4

2

0

SO

A (

µg

m-3

)

2520151050POA (µg m

-3)

R2 = 0.17

0.80.60.40.20.0

Org

/PM

1

1:1 line

PM1 (µg m-3

)20 25

Page 51: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

51

1323 Fig. 11 The scatter plots of each organic component (µg m−3) versus organics during haze 1324

periods (definite as organics > 43 µg m−3 (Org_avg + 1σ)) 1325

1326

6

4

2

0

HO

A

1209060

R2 = 0.1

6

4

2

0

BB

OA

1209060

R2 = 0.04

50

40

30

20

10

0

CO

A

1209060

R2 = 0.51 10

8

6

4

2

0

CC

OA

1209060

R2 = 0.19

12

8

4

0

LO

-OO

A

1209060

R2 = 0.15 10

8

6

4

2

0

LV-O

OA

1209060

R2 = 0.00

70 100

Org. (µg m-3

)

Org. (µg m-3

)

Page 52: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

52

1327 Fig. 12 The comparisons of (a) OC concentration measured by filter sample (OCFilter) and 1328

AMS (OCAMS) on Jan. 15 and 23, 2014 and (b) the non-fossil (NF) and fossil (F) carbon 1329

fraction measured by 14C and OC components in AMS. 1330

1331

30

20

10

0

Mas

s C

onc.

g m

-3)

100

80

60

40

20

0

Pe

rce

nta

ge

(%

)

OCFilter OCAMS OCFilter OCAMS

OCFilter OCAMS OCFilter OCAMS

F

NF

OOC

BBOC +COC

HOC +CCOC

Jan. 15, 2014 All data

Jan. 15, 2014 Jan. 23, 2014(a)

(b)

OCFilter OCAMS

Jan. 23, 2014

Page 53: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

53

1332

Fig. 13 The non-fossil (NF) and fossil (F) carbon fraction in POC and SOC during Jan. 1333

15, Jan. 23 and all data of AMS. 1334

1335

17% 33%

16% 34%

POC, Jan.15 SOC, Jan.15

POC, All SOC, All

17% 33%

16% 34%

15% 35%

18% 32%

16% 21%

13%

50%

16% 21%

13%

50%

15% 35%

18% 32%

32%

68%

56%

44%

34%

66%

SOC, Jan.23POC, Jan.23

F

NF

HOC

CCOC

BBOC

COC

Page 54: Wintertime organic and inorganic aerosol in Lanzhou · 2016-12-05 · 48 during wintertime in Lanzhou (average wind speed: 0.82 m s−1). 49 50 The average mass spectrum of OA showed

54

1336

Fig. 14 (a) Van Krevelen diagram for OA and (b) scatter plot of MO-OOA vs. Ox (the 1337

sum of O3 and NO2) with linear fit and colored by time of day. 1338

1339

1340

2.0

1.0

0.0

H:C

1.20.80.40.0O:C

OS=-2

OS=-1

OS=0m=-2+ketone/aldehyde

m=0+alcohol/peroxide

m=-1+carboxylic acid

slope = -0.8(a)

(b)8

6

4

2

0

MO

-OO

A (

µg

m-3

)

6050403020100Ox (ppbv)

R2 = 0.95

Slope = 0.11

00:0006:0012:0018:00

Tim

e o

f Day

BBOA (µg m-3

)

2 4